Buccal cirri

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Buccal cirri are feeding structures found in the oral hood of primitive jawless organisms called amphioxus. [1] The word buccal is derived from the term bucca which means "cheek" [2] and cirri is derived from the Latin word cerrus meaning a tendril or a small and flexible appendage. [3]

Contents

Structure

Cirri, plural for cirrus, are small, filament-like appendages that act like tentacles. Tentacles are elongated appendages from the cephalic region of organisms that aid in sensory and locomotive abilities. [4] Buccal cirri extend from the oral hood on the anterior portion of the organism. The buccal cirri possess receptors, some of which are believed to be mechanoreceptors. [5] Mechanoreceptors are sensory receptors on the surface of the body. The presence of external particles can be detected by an organism possessing buccal cirri due to the sensory abilities associated with the mechanoreceptors. Additionally, the touch and pressure sensory receptors aid in the mechanical sorting of food particles. Chemical sorting of particles occur through the use of chemoreceptors, which are believed to be present within the buccal cirri structure. Food and fluid particles passing through buccal cirri are sorted using chemoreceptors, which respond to chemical stimuli. Responses to stimuli are sent to higher order processing centers like the brain and nerve cord. The transmission of signals to higher order processing centers allows the organism to become aware of what type of particles are in and around the mouth. [6]

Function

Buccal cirri function as a food processing organ that is used to prevent larger particles from entering the oral hood. [7] The buccal cirri does this by working with the velar tentacles to create a comb like feeding appendage that sifts the particles that are entering via the water stream. This allows the smaller particles to continue through to the oral hood while the larger ones are brushed away. [8] The buccal cirri surround the buccal cavity in a ring like structure. They are thought to have chemoreceptors and mechanoreceptors that help detect food particles in the passing water stream. [6]

Organisms

Buccal cirri are found in organisms in the group called Amphioxus, which are commonly known as Lancelets. These organisms are in the kingdom Animalia, the phylum Chordata, the class Leptocardii, and the order Amphioxiformes. [9] Lancelets are classified in the taxonomic group cephalochordates. [5] There are thirty two different species of Lancelets in the order of Amphioxiformes. [10] Lancelets feed through a process of filter feeding using buccal cirri, velar tentacles, velum, wheel organ, Hatschek's pit, and the tracts in the pharynx called the endostyle and epibranchial groove. [11]

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<span class="mw-page-title-main">Sensory nervous system</span> Part of the nervous system responsible for processing sensory information

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<span class="mw-page-title-main">Tentacle</span> Varied organ found in many animals and used for palpation and manipulation

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<span class="mw-page-title-main">Cephalochordate</span> Subphylum of lancelets

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<span class="mw-page-title-main">Lancelet</span> Order of chordates

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<span class="mw-page-title-main">Cephalization</span> Evolutionary trend of a head region developing

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<span class="mw-page-title-main">Star-nosed mole</span> Species of Mole

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<span class="mw-page-title-main">Pharyngeal slit</span> Repeated openings that appear along the pharynx of chordates

Pharyngeal slits are filter-feeding organs found among deuterostomes. Pharyngeal slits are repeated openings that appear along the pharynx caudal to the mouth. With this position, they allow for the movement of water in the mouth and out the pharyngeal slits. It is postulated that this is how pharyngeal slits first assisted in filter-feeding, and later, with the addition of gills along their walls, aided in respiration of aquatic chordates. These repeated segments are controlled by similar developmental mechanisms. Some hemichordate species can have as many as 200 gill slits. Pharyngeal clefts resembling gill slits are transiently present during the embryonic stages of tetrapod development. The presence of pharyngeal arches and clefts in the neck of the developing human embryo famously led Ernst Haeckel to postulate that "ontogeny recapitulates phylogeny"; this hypothesis, while false, contains elements of truth, as explored by Stephen Jay Gould in Ontogeny and Phylogeny. However, it is now accepted that it is the vertebrate pharyngeal pouches and not the neck slits that are homologous to the pharyngeal slits of invertebrate chordates. Pharyngeal arches, pouches, and clefts are, at some stage of life, found in all chordates. One theory of their origin is the fusion of nephridia which opened both on the outside and the gut, creating openings between the gut and the environment.

<span class="mw-page-title-main">Shark anatomy</span>

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<span class="mw-page-title-main">Mouth</span> First portion of the alimentary canal that receives food

The mouth is the body orifice through which many animals ingest food and vocalize. The body cavity immediately behind the mouth opening, known as the oral cavity, is also the first part of the alimentary canal which leads to the pharynx and the gullet. In tetrapod vertebrates, the mouth is bounded on the outside by the lips and cheeks — thus the oral cavity is also known as the buccal cavity — and contains the tongue on the inside. Except for some groups like birds and lissamphibians, vertebrates usually have teeth in their mouths, although some fish species have pharyngeal teeth instead of oral teeth.

A sense is a biological system used by an organism for sensation, the process of gathering information about the world through the detection of stimuli. Although in some cultures five human senses were traditionally identified as such, many more are now recognized. Senses used by non-human organisms are even greater in variety and number. During sensation, sense organs collect various stimuli for transduction, meaning transformation into a form that can be understood by the brain. Sensation and perception are fundamental to nearly every aspect of an organism's cognition, behavior and thought.

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<i>Branchiostoma lanceolatum</i> Species of lancelet

Branchiostoma lanceolatum, the European lancelet or Mediterranean amphioxus, is a lancelet in the subphylum Cephalochordata. It is a marine invertebrate with a notochord but no backbone and is used as a model organism to study the evolutionary development of vertebrates.

Amphioxus or lancelets (Branchiostoma) are members of the Chordata phylum of which all members have a notochord at some point while they are alive. B. belcheri have a notochord, dorsal nerve cord, pharynx, buccal cavity, cirri, tail, dorsal fin, nerve cord, segmented muscle, and ocelli. They are distinguishable by a slightly round dorsal fin, eighty slender preanal fin-chambers, narrow caudal fin, and obtuse angles between fins. They obtain food by filter feeding. They were first reported in 1897 near the Amakusa Islands, specifically off Goshonoura Island, south of Amakusa-Kamishima Island. These islands are located on the west coast of Kyushu, the island furthest south of the four main isles of Japan. In addition to the location of the siting, information regarding reproductive period and morphology was also obtained. B. belcheri are gonochoric, reproducing via external fertilization. B. belcheri are an endangered species, threatened by the influx of pollutants of land-based origin into the sea such as cleaning agents, chemical waste, garbage, mining waste, pesticides, petroleum products, and sewage.

References

  1. "Cephalochordata, Laboratory Notes for BIO 1003". faculty.baruch.cuny.edu. Retrieved 2016-11-08.
  2. Peyer, Bernhard (1968). Comparative Odontology. Chicago, Illinois: The University of Chicago Press. p. 15.
  3. "cirrus". The Free Dictionary.
  4. "Tentacles - Biology-Online Dictionary". www.biology-online.org. Retrieved 2016-11-08.
  5. 1 2 Fishbeck, Dale (2008). Manual of Vertebrate Dissection: Comparative Anatomy. Morton Publishing Company. pp. 21–22. ISBN   9780895827487.
  6. 1 2 "Untitled 1". lanwebs.lander.edu. Retrieved 2016-11-08.
  7. Kardong, Kenneth V. (2015). Vertebrates Comparative Anatomy, Function, Evolution. New York, New York: McGraw Hill Education. p. 62. ISBN   978-0-07-802302-6.
  8. Wolff, Ronald G. (1991). Functional Chordate Anatomy. Lexington, Massachusetts: D.C. Heath and Company. pp. 342–343. ISBN   0-669-21895-2.
  9. "ADW: Amphioxiformes: CLASSIFICATION". animaldiversity.org. Retrieved 2016-11-08.
  10. "eolspecies.lifedesks.org: EOLspecies". archive.is. Retrieved 2016-11-08.
  11. Kardong, Kenneth (2015). Comparative Vertebrate Anatomy: A Laboratory Dissection Guide. New York, New York: McGraw Hill. pp. 11–12. ISBN   9780077657055.
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